JP2006261564A - Common-mode choke coil - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a common-mode choke coil which reduce variations in characteristic impedance by keeping intervals of conductors constant. <P>SOLUTION: A core 3 has a 1st cut 33a near the intersection of a first side face 33 and the back of a collar 4 by slightly recessing the surface toward a 2nd side face 34, a 1st corner is formed at a connection portion between the 1st cut 33a and back, and a second corner 33c is formed at a connection place between the 1st side face 33 and first cut 33a. The second side face 34 also has a second cut 34a, a third corner 34b, and a fourth corner 34c formed similarly. A first conductor 6 and a second conductor 7 extends from a wiring place of a first electrode 8 to the first cut 33a, and is arranged along the first corner and second corner 33c to be wound. Then they are wound up to the second cut 34a arranged along the fourth corner 34c and a third corner 33b, and wired to the second electrode 9. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a common mode choke coil.

  In recent years, high-frequency transmission signals are used in the USB 2.0 standard, which is a high-speed interface in personal computers, and the HDMI standard, which is a digital video / audio input / output interface such as digital video. As the transmission signal becomes higher in frequency, signals having a phase difference of 180 ° are passed through two conductors, and signals are transmitted by a differential transmission method that is hardly affected by noise and has few signal errors.

  However, in reality, for example, a common mode noise current may be generated due to a difference in communication characteristics between two conductors, and noise may be emitted using the conductor as an antenna. For example, the coil component shown by patent document 1 is disclosed.

Further, in a coil component used for an interface using a high-frequency transmission signal, in order to determine its characteristic impedance, the line capacitance is remarkably related in addition to the inductance of the coil component.
JP 2003-133148 A

  However, in the coil component disclosed in Patent Document 1, since there is no portion to be positioned when winding the conducting wire around the winding core portion, the winding of the conducting wire is not uniform, and the line capacity varies. It was. Therefore, the characteristic impedance of the coil component also varies.

  In order to reduce this variation, the inventors of the present invention have found that the line-to-line capacitance varies with the distance between the two conductors. SUMMARY OF THE INVENTION An object of the present invention is to provide a common mode choke coil in which variation in characteristic impedance is reduced by keeping the interval between conducting wires constant.

  In order to achieve the above object, the present invention provides a core having a columnar core portion and first and second collar portions provided at both ends of the core portion, and a core wound on the surface of the core portion. The first and second conductors to be rotated, the first electrode provided at the first collar and connected to one end of the first conductor, and the one end of the second conductor connected to the first collar and the first conductor A second electrode provided on the second hook and the third electrode connected to the other end of the second conductor, and a second electrode provided on the second hook and connected to the other end of the first conductor. Four electrodes, the winding direction of the first conductor and the second conductor is the length direction, the direction connecting the first electrode and the second electrode to each other is the first width direction, the length direction and the first When the direction perpendicular to the width direction is the first thickness direction, the first conductor and the second conductor extended from the first collar are started to be wound on the first collar part side of the core part. Almost no A first notch is formed on the side surface in the thickness direction and close to the first electrode over substantially the entire first thickness direction, and the first conductor and the second conductor are aligned in the first notch. A common mode choke coil is provided.

  According to such a structure, the winding start position of the conducting wire wound around the core part can be defined. Therefore, the winding position of the two conducting wires is prevented from being shifted during winding, and it is difficult for winding collapse to occur after winding. Therefore, the distance between the two conductors hardly changes, and the line capacitance can be kept constant.

  In the common mode choke coil having the above-described configuration, it is preferable that the first notch is formed along the connecting portion between the core portion and the first flange portion. According to such a structure, a conducting wire can be wound from the 1st collar part side edge part of a core part, and a core part can be utilized effectively. Moreover, since the connection part of a 1st collar part and a core part can be made into a part of 1st notch at all, the shape of a core can be simplified and core shaping | molding becomes easy.

  The first corner is provided with a first corner on the first collar side and a second corner on the anti-first collar side extending substantially in the first thickness direction. It is preferable that the first conductor is disposed along the first corner, and the second conductor is wired from the second electrode along the second corner. According to such a configuration, the arrangement of the two conducting wires can be made more accurate, and the line-to-line capacitance can be kept constant more accurately.

  Also, on the second flange side of the winding core portion, the direction connecting the third electrode and the fourth electrode to each other is the second width direction, and the direction orthogonal to the length direction and the second width direction is the first direction. When defined as the two-thickness direction, on the side surface in the substantially second thickness direction where the first conductor wire and the second conductor wire have been wound, and on the side surface close to the third electrode, substantially over the entire second thickness direction. It is preferable that a second notch is formed and the first conductor and the second conductor are arranged side by side in the second notch.

  According to such a structure, it can be set as the structure similar to a 1st collar part side core part also in a 2nd collar part side core part. Therefore, a common mode choke coil can be manufactured regardless of the direction of the length direction of the core, and productivity can be improved.

  Moreover, it is preferable that the 2nd notch is formed along the connection part of a core part and a 2nd collar part. According to such a structure, a conducting wire can be wound to the 2nd collar part side edge part of a core part, and a core part can be used still more effectively.

  The second notch is provided with a second triangular portion on the second flange side and a fourth square portion on the side opposite to the second flange portion extending substantially in the second thickness direction, and the second conductor is provided on the second triangular portion. It is preferable that the first conductive wire is arranged along the fourth corner portion and is connected to the fourth electrode. According to such a configuration, the arrangement of the two conductors can be made accurate at both the winding start position and the winding end position, and the line-to-line capacity can be kept constant more accurately.

  In addition, the first hook portion includes a first latching portion located immediately downstream in the winding direction of the first electrode, and a first hooking portion spaced apart from the first latching portion in the first width direction and immediately downstream in the winding direction of the second electrode. And a first lead wire extending from the first electrode is hooked to the first hook portion and disposed along the first corner portion, and extends from the second electrode. The second wire to be taken out is hooked on the second hooking portion and arranged along the second corner portion, and the second hook portion has a third hooking located on the upstream side in the winding direction of the third electrode. And a fourth latching portion that is spaced apart from the third latching portion in the second width direction and is located immediately upstream in the winding direction of the fourth electrode, and the second conductor extended from the third triangular portion is The first conductor that is hooked on the third hook and connected to the third electrode and extended from the fourth corner may be hooked on the fourth hook and connected to the fourth electrode. preferable. According to such a configuration, the position of the conductive wire extending from the electrode to the core portion can be more accurately maintained at a predetermined position.

  Moreover, it is preferable that a plurality of convex portions are provided on the surface of the winding core portion, and the first conductive wire and the second conductive wire are wound while passing between adjacent convex portions while being separated from each other. According to such a configuration, when winding the conducting wire around the core portion, one turn of the two conducting wires can be sequentially wound between the adjacent projecting portions, and each turn of the conducting wire is projected. It can be partitioned by part. Therefore, the distance per turn of the conducting wire can be controlled by the convex portion. Since the distance per turn of the conducting wire can be controlled, the line-to-line capacitance per turn of the conducting wire can be controlled.

  In addition, with the first conductor and the second conductor wound around the core, the distance between the first conductor and the second conductor is substantially uniform, and the first conductor and the second conductor are wound around the core. It is preferable that the intervals to be rotated are substantially uniform. According to such a configuration, the line capacitance can be made constant.

  According to the common mode choke coil of the present invention, since the line capacitance is constant, it is possible to provide a common mode choke coil with reduced variation in characteristic impedance.

  A coil component according to an embodiment of the present invention will be described with reference to FIGS. A common mode choke coil 1 shown in FIG. 1 mainly includes a drum-shaped core 2, a first conductive wire 6 and a second conductive wire 7, and a first electrode portion 8 and a second electrode portion 9. .

  The core 2 is a magnetic body and has a substantially rectangular core part 3 having a substantially rectangular cross section perpendicular to the longitudinal direction, a first flange part 4 having substantially the same shape provided at one end and the other end in the longitudinal direction of the core part 3 and It is comprised from the 2nd collar part 5. As shown in FIG. As shown in FIG. 2, the winding direction of the first conductor 6 and the second conductor 7 is the x-axis direction and the width direction of the core section, which is the longitudinal direction of the core section 3 and the first section described later. The direction connecting the electrode 8A and the second electrode 8B to each other is the y-axis direction (first and second width directions) and, as shown in FIG. A direction orthogonal to the y-axis direction will be described as the z-axis direction (first and second thickness directions).

  As shown in FIGS. 2 and 3, the core portion 3 includes a first surface 31 that is a width direction surface, a second surface 32 that is the opposite surface of the first surface 31, a first surface 31, and a second surface. The first side surface 33 and the second side surface 34 which are thickness direction surfaces provided between the surface 32 and the surface 32 are configured. The first surface 31 and the second surface 32 are substantially parallel to each other, and the first side surface 33 and the second side surface 34 are also substantially parallel to each other. Therefore, the yz plane cross section of the core part 3 is substantially rectangular.

  As shown in FIGS. 2 and 3, in the vicinity of the portion where the first side surface 33 of the first side surface 33 intersects the back surface 42 described later, the surface of the first side surface 33 extends slightly in the direction of the second side surface 34 over substantially the entire z-axis direction. A recessed first notch 33a is formed. A first corner portion 33b is provided at the connecting portion between the first notch 33a and the back surface 42, and the first notch 33a and the first side surface are connected to the connecting portion between the first side surface 33 and the first notch 33a. A second corner 33 c, which is a step with respect to 33, is formed. As shown in FIG. 2, a second notch 34 a similar to the first notch 33 a is also formed in the vicinity of a portion where the second side surface 34 of the second side surface 34 and a back surface 52 described later intersect. A connecting portion between the second notch 34a and the back surface 52 is provided with a third triangular portion 34b. A connecting portion between the second side surface 34 and the second notch 34a is provided with a second notch 34a and a second side surface 34. A fourth corner portion 34c that is a step is formed.

  As shown in FIGS. 2 and 3, a plurality of first protrusions 31 </ b> A to 31 </ b> D arranged at equal intervals in the x-axis direction are provided at the approximate center of the first surface 31 in the y direction. A plurality of second recesses 32 </ b> A to 32 </ b> C aligned at equal intervals in the x-axis direction are also provided at the approximate center of the second surface 32 in the y direction. The first convex portions 31A to 31D and the second convex portions 32A to 32C are all substantially the same shape, and the cross-sectional area on the base end side is larger than the cross-sectional area on the distal end side, and has a chevron shape with no overhang. (FIG. 3), the surface forms a slope with respect to the surface of the core part 3.

  As shown in FIG. 3, in the x-axis direction, the second convex portion 32 </ b> A is disposed at a substantially intermediate position between the first convex portion 31 </ b> A and the first convex portion 31 </ b> B. As shown in FIGS. 2 and 4, the first region 3A is between the first convex portion 31A and the first convex portion 31B, and the second region is between the second convex portion 32A and the second convex portion 32B. 3B, the third region 3C is between the first convex portion 31B and the first convex portion 31C, the fourth region 3D is between the second convex portion 32B and the second convex portion 32C, and the first convex portion 31C and the first convex portion 31C. A space between the convex portion 31D is defined as a fifth region 3E.

  As shown in FIGS. 2 and 3, the first flange portion 4 includes a front surface 41 and a back surface 42 orthogonal to the x-axis direction, a first side surface 43 and a second side surface 44 orthogonal to the y-axis direction, and a z-axis. It is comprised from the substantially rectangular parallelepiped prescribed | regulated from the top surface 45 and the bottom face 46 orthogonal to a direction. Similarly, the second flange portion 5 is also a substantially rectangular parallelepiped defined by the front surface 51 and the back surface 52, the first side surface 53 and the second side surface 54 orthogonal to the y-axis direction, and the top surface 55 and the bottom surface 56 orthogonal to the z-axis direction. It is made up of.

  As shown in FIG. 2, the top surface 45 is formed with a pair of first groove portions 45 a and second groove portions 45 b that are inclined from the approximate center position of the top surface 45 in the x-axis direction toward the core portion 3. Has been. The first groove part 45a and the second groove part 45b are configured symmetrically with respect to the x-axis passing through the center of the top surface 45 in the y-axis direction. A first latching portion 45 </ b> A is defined at a step formed by the first groove portion 45 a of the top surface 45 and on the side near the first side surface 33 in the y-axis direction. Further, a second hooking portion 45B is defined in the step formed between the second groove portion 45b and the first groove portion 45a.

  Similarly, a pair of third groove portion 55a and fourth groove portion 55b are formed on the top surface 55 of the second flange portion 5 so as to be inclined from the approximate center position in the x-axis direction on the top surface 55 toward the core portion 3. The third groove portion 55a and the fourth groove portion 55b are symmetric with respect to the x axis passing through the center of the top surface 55 in the y axis direction. Further, a third latching portion 55A is defined at a step formed by the third groove portion 55a of the top surface 55 and on the side near the second side surface 34 in the y-axis direction. Further, a fourth latching portion 55B is defined in the step formed between the fourth groove portion 55b and the third groove portion 55a.

  The first electrode portion 8 has a first electrode 8A on the first side surface 43 side and a second electrode 8B on the second side surface 44 side in line in the y-axis direction. As shown in FIG. 1, the first electrode 8 </ b> A and the second electrode 8 </ b> B are formed by plating across the top surface 45 and the front surface 41. Further, on the top surface 45, a part of the first electrode 8A is also formed in the first groove part 45a, and a part of the second electrode 8B is also formed in the second groove part 45b. The top surface 45 portion of the first electrode portion 8 serves as a connection portion between the first conductor 6 and the second conductor 7.

  As shown in FIG. 2, like the first electrode portion 8, the second electrode portion 9 is arranged in the y-axis direction, the third electrode 9 </ b> A on the first side surface 53 side, and the fourth electrode 9 </ b> B on the second side surface 54 side. have. The third electrode 9A and the fourth electrode 9B are formed by plating over the top surface 55 and the front surface 51. On the top surface 55, a part of the third electrode 9A is also formed in the third groove part 55a, and a part of the fourth electrode 9B is also formed in the fourth groove part 55b. The top surface 55 portion of the second electrode portion 9 serves as a connection portion between the first conductor 6 and the second conductor 7. In addition, since the 2nd collar part 5 is substantially the same shape as the 1st collar part 4, and is formed in the symmetrical shape on both sides of the core part 3, it connects the 1st electrode 8A and the 2nd electrode 8B mutually. The direction and the direction connecting the third electrode 9A and the fourth electrode 9B to each other are substantially the same direction.

  As shown in FIG. 2, the first conducting wire 6 has one end 6A connected to the first electrode 8A and disposed in the first groove 45a so as to be hooked on the first hooking portion 45A. And it arrange | positions on the back surface 42, is extended to the 1st notch 33a side, is arrange | positioned in the 1st notch 33a along the 1st corner | angular part 33b, and begins to wind around the core part 3. FIG.

  One end 7A of the second conducting wire 7 is connected to the second electrode 8B, and the second conducting wire 7 is disposed in the second groove 45b and is hooked to the second hooking portion 45B. And it extends to the first notch 33a side along the first convex portion 31A vicinity of the first surface 31 and is disposed in the first notch 33a along the second corner portion 33c to be wound around the core portion 3. You can start turning. The first conducting wire 6 is wound along the first corner portion 33b, and the second conducting wire 7 is wound along the second corner portion 33c, whereby winding of the first conducting wire 6 and the second conducting wire 7 is started. The position can be accurately defined. In addition, the first conducting wire 6 and the second conducting wire 7 are arranged in the first notch 33a after being hooked on the first and second latching portions 45A and 45B, so that the first missing portion from the connecting portion is completely absent. The arrangement of the first conductor 6 and the second conductor 7 can be made accurate up to 33a.

  As shown in FIG. 4, the second conducting wire 7 disposed along the second corner portion 33 c is wired along the surface of the second surface 32 and along the first flange portion 4 side of the second convex portion 32 </ b> A. The first side 31 is wound through the second side 34. Further, as shown in FIG. 2, the second conducting wire 7 wound from the first side surface 33 side is the surface of the first surface 31 and extends into the first region 3A, and the first convex portion 31B and It is wired so as to abut, and is wound around the second surface 32 side via the first side surface 33.

  Further, as shown in FIG. 4, the first conductor 6 after being arranged along the first corner portion 33 b is wired on the surface of the second surface 32, and on the first surface 31 side via the second side surface 34. It is wound. Furthermore, as FIG. 2 shows, the 1st conducting wire 6 wound from the 2nd side surface 34 side is the 1st surface 31 surface, is extended in the 1st area | region 3A, 1st convex part 31B, It is wired so as to abut and is wound around the second surface 32 side.

  Since the interval between the first convex portion 31A and the first convex portion 31B is a constant distance, and the first convex portion 31A and the first convex portion 31B have the same shape, The distance between the first conducting wire 6 and the second conducting wire 7 is kept constant.

  As shown in FIG. 4, the second conductor 7 wound from the first region 3A to the second surface 32 through the second side surface 34 is the surface of the second surface 32 and is in the second region 3B. It is extended, wired so as to come into contact with the second convex portion 32 </ b> B, and wound around the first surface 31 via the second side surface 34. Moreover, the 1st conducting wire 6 wound from the 1st area | region 3A to the 2nd surface 32 via the 1st side surface 33 is also the 2nd surface 32 surface, and is extended in the 2nd area | region 3B, and a 2nd convex part. It is wired so as to abut on 32A and is wound around the first surface 31 side via the second side surface.

  In the second region 3B, the distance between the second convex portion 32A and the second convex portion 32B is equal to the distance between the first convex portion 31A and the first convex portion 31B, and the shape thereof is the first convex portion. Since it has the same shape as 31A, it has substantially the same shape as the first region 3A. Therefore, the distance between the first conductor 6 and the second conductor 7 is also the same as the distance between the first conductor 6 and the second conductor 7 in the first region 3A.

  Similarly, since the third region 3C, the fourth region 3D, and the fifth region 3E have substantially the same shape as the first region 3A, the first region in the third region 3C, the fourth region 3D, and the fifth region 3E. The distance between the conducting wire 6 and the second conducting wire 7 is also maintained at the same value. Therefore, when the first conducting wire 6 and the second conducting wire 7 in each region are wound around the core portion 3, the distance in the x direction is kept constant, and so-called space winding is formed.

  As shown in FIG. 2, the first region 3A, the third region 3C, and the fifth region 3E on the first surface 31 are partitioned by the first convex portion 31B and the first convex portion 31C having the same shape. As shown in FIG. 4, the second region 3B and the fourth region 3D on the second surface 32 are partitioned by the second convex portion 32B. Since all of the first convex portions 31A to 31D and the second convex portions 32A to 32C have substantially the same shape, the distances between adjacent regions are also substantially equal.

  Moreover, in each area | region, since the 1st conducting wire 6 and the 2nd conducting wire 7 are provided in contact with the convex part which divides each area | region, the 1st conducting wire 6 and the 2nd conducting wire 7 which are arrange | positioned in 3 A of 1st areas | regions are provided. Between the first conductor 6 and the second conductor 7 disposed in the third region 3C and the first conductor 6 and the second conductor 7 disposed in the third region 3C and the fifth region 3E. The distance between the first conductor 6 and the second conductor 7 is substantially equal. The distance between the first conductor 6 and the second conductor 7 arranged in the first area 3A and the first conductor 6 and the second conductor 7 arranged in the third area 3C and the second conductor 3B are arranged. The distances between the first conductor 6 and the second conductor 7 and the first conductor 6 and the second conductor 7 arranged in the fourth region 3D are also substantially equal.

  Therefore, when the 1st conducting wire 6 and the 2nd conducting wire 7 are wound around the core part 3, the distance for every turn which made the 1st conducting wire 6 and the 2nd conducting wire 7 1 set is at least 1st area | region 3A. To a fifth region 3E.

  As shown in FIG. 4, the second conducting wire 7 extended from the fifth region 3E is wound to the second surface 32 side through the first side surface 33, and the surface of the second surface 32 is second notched 34a. It extends toward the side and is arranged at the position of the third triangular portion 34b. And the 2nd conducting wire 7 is arrange | positioned in the 2nd notch 34a along the 3rd triangular part 34b, and as shown in FIG. 2, it arrange | positions on the back surface 52 and is latched by the 3rd latching | locking part 55A. . And it arrange | positions in the 3rd groove part 55a, is extended to the 3rd electrode 9A side, and the other end 7B is connected to 9 A of 3rd electrodes.

  As shown in FIG. 4, the first conductive wire 6 extended from the fifth region 3 </ b> E is wound to the second surface 32 side via the first side surface 33, and the second convex portion on the surface of the second surface 32. It extends toward the second notch 34a side along the second flange part 5 side of 32C and is arranged at the position of the third triangular part 34b. And the 1st conducting wire 6 is arrange | positioned in the 2nd notch 34a along the 2nd corner | angular part 34c, and is arrange | positioned along 1st convex part 31D of the 1st surface 31, as FIG. 2 shows, It is hooked on the fourth hook 55B. And it arrange | positions in the 4th groove part 55b, is extended to the 4th electrode 9B side, and the other end 6B is connected to the 4th electrode 9B. The first conductive wire 6 is wound and connected along the fourth square portion 34c, and the second conductive wire 7 is wound and connected along the third triangular portion 34b. The winding end position of the two conductors 7 can be accurately defined. In addition, the first conductor 6 and the second conductor 7 extended from the second notch 34a are connected after being hooked to the fourth hook 55B and the third hook 55A. To the second notch 34a, the first conductor 6 and the second conductor 7 can be arranged accurately.

  Moreover, when winding the 1st conducting wire 6 and the 2nd conducting wire 7 around the core part 3, the 1st conducting wire 6 may be wound on 31 A of 1st convex parts, for example. However, since the surface of the first convex portion 31A is an inclined surface, the first conductive wire 6 slides on the surface of the first convex portion 31A, and the first convex portion that is the location where the first convex portion 31A and the first surface 31 intersect. It is placed in the 31A cage. Therefore, by winding the 1st conducting wire 6 and the 2nd conducting wire 7 around the core part 3 so that it may slightly hang over the 1st convex parts 31A-31D and the 2nd convex parts 32A-32C, the 1st convex parts 31A-. It can wind so that the 1st conducting wire 6 and the 2nd conducting wire 7 may contact | abut correctly on the collar of 31D and 2nd convex part 32A-32C.

  In the common mode choke coil 1 configured as described above, it is possible to accurately define the winding start position and the winding end position on the winding core portion 3, so that variations in characteristics among products can be reduced. . Further, the common mode choke coil 1 has the same shape of the first collar portion 4 and the second collar portion 5 and is symmetrical with respect to the center position of the core portion 3 on the xy plane. Thus, when the common mode choke coil 1 is manufactured, any one of the pair of flange portions provided at both ends of the core portion 3 may be the first flange portion 4 in the positional relationship in the x-axis direction. . Accordingly, it is not necessary to align the cores 2 in the x-axis direction at the time of manufacture, so unnecessary labor can be omitted and productivity can be improved.

  The line capacity of the common mode choke coil 1 varies depending on the distance between the first conductor 6 and the second conductor 7 and the distance of each turn of the first conductor 6 and the second conductor 7. In the common mode choke coil 1 according to the embodiment, since these distances are kept constant among the products, a common mode choke coil having a substantially constant line capacitance can be provided. The characteristic impedance of the common mode choke coil varies depending on the line capacitance, but the distance between the first conductor 6 and the second conductor 7 and the distance per turn of the first conductor 6 and the second conductor 7 are different. Since it is possible to reduce the variation in line capacitance between products while being kept constant, it is possible to provide a common mode choke coil having a constant characteristic impedance between the products. Therefore, it is possible to provide a common mode choke coil that suitably eliminates a specific frequency with reduced variation in characteristic impedance between products.

  The coil component according to the present invention is not limited to the above-described embodiment, and various modifications and improvements can be made within the scope described in the claims. For example, you may use the core of the shape which does not provide a convex part. Even in this case, at least the winding start position and the winding end position of the conducting wire of the winding core portion are accurately defined, so that variations in characteristics among the products can be reduced. In addition, since the winding start position and winding end position of the conducting wire are in the notch, it is difficult for the conducting wire to deviate between the winding starting position and the winding end position. Suppressing the deviation of the conducting wire is suppressed.

The perspective view of the common mode choke coil which concerns on embodiment of this invention. The top view of the common mode choke coil which concerns on embodiment of this invention. The side view of the common mode choke coil which concerns on embodiment of this invention. The bottom view of the common mode choke coil which concerns on embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 .. Common mode choke coil 2 .. Core 3 .. Core part 3A-3E .. 1st area | region-5th area | region 31 .. 1st surface 31A-31D .. 1st convex part 32 .... 2nd surface 32A to 32C, second convex portion 33, first side 33a, first notch 33b, first corner 33c, second corner 34, second side 34a, second notch 34b ..Triangular part 34c..Fourth square part 4..First collar part 41..Front side 42.-Back side 43.-First side surface 44.-Second side surface 45..Top surface 45A..First hook Stop 45B ··· Second hook 45a · · · First groove 45b · · · Second groove 46 · · Bottom 5 · · · second collar 51 · · · Front 52 · · · Back 53 · · · First side 54 · · · Second side 55 ·· Top surface 55A ·· Third hook portion 55B ·· Fourth hook portion 55a ·· Third groove portion 55b ·· Fourth groove portion 56 ·· Bottom 6 .. The first wire 7 .. second conductor 8 ... first electrode portion 8A ... first electrode 8B ... second electrode 9 ... second electrode portion 9A ... third electrode 9B ... fourth electrode

Claims (9)

A core having a columnar core part and first and second collar parts provided at both ends of the core part, and a first conductor and a second conductor wound around the surface of the core part A first electrode provided at the first flange and connected to one end of the first conductor, and a second electrode provided at the first flange and connected to one end of the second conductor. A third electrode provided on the second flange and connected to the other end of the second conductor; and a fourth electrode provided on the second flange and connected to the other end of the first conductor. And
The winding direction of the first conductor and the second conductor is the length direction, the direction connecting the first electrode and the second electrode to each other is the first width direction, and the length direction and the first When the direction perpendicular to the width direction is the first thickness direction, on the first flange portion side of the core portion, the first conductor and the second conductor extended from the first flange are A first notch is formed on the side surface substantially in the first thickness direction which is started to be wound and close to the first electrode, over the entire first thickness direction. And a common mode choke coil, wherein the second conducting wire is arranged in the first notch.   2. The common mode choke coil according to claim 1, wherein the first notch is formed along a connecting portion between the core portion and the first flange portion.   The first notch is provided with a first corner on the first collar side and a second corner on the anti-first collar side extending substantially in the first thickness direction, and the first conductor is The first electrode is disposed along the first corner, and the second conductor is wired from the second electrode along the second corner. The common mode choke coil according to any one of 2 above.   On the second flange side of the winding core portion, a direction connecting the third electrode and the fourth electrode to each other is a second width direction, and the length direction and the second width direction are When the direction perpendicular to the second thickness direction is defined, the side surface in the second thickness direction where the first conductive wire and the second conductive wire have been wound and the side surface close to the third electrode is substantially The second notch is formed over the entire second thickness direction, and the first conductor and the second conductor are arranged side by side in the second notch. The common mode choke coil according to claim 3.   5. The common mode choke coil according to claim 4, wherein the second notch is formed along a connecting portion between the winding core portion and the second flange portion.   The second notch is provided with a second triangular portion on the second flange side and a fourth corner portion on the side opposite to the second flange portion extending in a substantially second thickness direction, and the second conductor is The first conductor is disposed along the fourth triangular portion and connected to the third electrode, and the first conductor is disposed along the fourth corner and connected to the fourth electrode. The common mode choke coil according to claim 4 or claim 5. The first hook portion includes a first latching portion located immediately downstream in the winding direction of the first electrode, and the first hooking portion spaced apart from the first latching portion in the first width direction. A second latching portion located immediately downstream in the rotational direction is provided, and the first conducting wire extending from the first electrode is latched by the first latching portion and along the first corner portion The second conducting wire disposed and extended from the second electrode is hooked on the second hooking portion and is arranged along the second corner portion;
The second hook portion includes a third hook portion located immediately upstream in the winding direction of the third electrode, and a third hook portion spaced apart from the third hook portion in the second width direction. A fourth latching portion located immediately upstream in the rotation direction is provided, and the second conducting wire extending from the triangular portion is hooked to the third latching portion and connected to the third electrode. The common mode choke coil according to claim 6, wherein the first conducting wire extending from the fourth corner portion is hooked to the fourth hooking portion and connected to the fourth electrode. .   A plurality of convex portions are provided on a surface of the core portion, and the first conductive wire and the second conductive wire are wound while passing between adjacent convex portions while being separated from each other. The common mode choke coil according to any one of claims 1 to 7.   In a state where the first conductor and the second conductor are wound around the core, the distance between the first conductor and the second conductor is substantially uniform, and the first conductor and the second conductor 9. The common mode choke coil according to claim 1, wherein an interval at which the coil is wound around the winding core portion is substantially uniform.

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